JP3840898B2 - Projection display device, display method therefor, and image display device - Google Patents

Description

[0001]
【Technical field】
The present invention relates to an image display device, and more particularly to a technology of a projection display device that projects and displays an image.
[0002]
[Background]
Projection-type display devices are often used for presentations because an input image can be enlarged and displayed on a projection screen.
[0003]
In the presentation, explanation is made based on the projected image, and usually a multi-page presentation image is used. The presentation images on each page show different contents, but several presentation images are often related to each other. In such a case, conventionally, a plurality of related pages of presentation images are displayed while being switched. However, there has been a desire to simultaneously display only a related portion of a plurality of pages of presentation images.
[0004]
In addition, in the case of a question and answer session in a presentation or when it takes some time until a new projected image is displayed, a company logo mark or product image prepared in advance instead of the image used for the presentation ( Hereinafter, it may be referred to as “specific image”) to appeal the company or product. Conventionally, such a specific image has been supplied to the projection display device via an image supply device (computer, video player, television receiver, etc.) connected to the projection display device. That is, in order to display the specific image on the projection display device, there is a problem that the image data of the specific image must be stored in advance in an image supply device connected to the projection display device.
[0005]
By the way, when no image is input to the projection display device, nothing is displayed on the screen. In such a case, the conventional projection display device displays a one-color screen called a blank image. Even in such a case, there is a desire to display the specific image as described above. However, in this case, since a normal image is not input from the image supply device, the specific image cannot be displayed. The above problem is not limited to the projection display device, but is common to image display devices that display images supplied from the outside.
[0006]
DISCLOSURE OF THE INVENTION
The present invention has been made in order to solve the above-described problems in the prior art, and a first object thereof is to provide a technique capable of simultaneously displaying related portions of a plurality of pages of images. A second object is to provide a technique capable of displaying a desired specific image even when the specific image is not supplied from the outside.
[0007]
In order to solve at least a part of the above-described problem, a projection display device according to a first aspect of the present invention includes an image extraction unit that extracts at least a part of input first image data as an extracted image; The extracted image memory for storing extracted image data representing the extracted image, and the original image and the extracted image are superimposed by superimposing the extracted image and the original image represented by the input second image data. An image superimposing unit that generates the superimposed image data, a light modulation unit that is driven for each pixel according to the superimposed image data, and the superimposed image obtained by driving the light modulation unit is projected onto the screen. And an optical system.
[0008]
The projection display device includes an image extraction unit that extracts an extracted image by cutting out at least a part of an image input therein, and an image superimposing unit that superimposes the extracted image on the original image. It is possible to simultaneously display related portions of images for a plurality of pages.
[0009]
In the projection display device, it is preferable that the part extracted by the image extraction unit from the first image data can be arbitrarily set.
[0010]
In this way, any part of the input image data can be used as an extracted image, so that extracted image data according to the purpose can be easily created.
[0011]
In the projection display device, it is preferable that the image superimposing unit arranges and extracts the extracted image at a desired position of the original image.
[0012]
In this way, the extracted image can be superimposed at an arbitrary position of the original image by the image superimposing unit, so that the degree of freedom for superimposing the extracted image is increased.
[0013]
In the projection display device, the extracted image memory stores a plurality of types of extracted image data representing a plurality of types of extracted images, and the image superimposing unit stores at least one selected extracted image, It is preferable to superimpose each of the original images at a designated position.
[0014]
In this way, an arbitrary extracted image can be selected from a plurality of types of extracted images, so that a desired extracted image can be superimposed on the original image.
[0015]
In the projection display device, the image superimposing unit generates the superimposed image data by synthesizing the input second image data and the extracted image data read from the extracted image memory. And a frame memory that has a memory area including at least an area corresponding to all pixels of the light modulation unit and stores the superimposed image data, and the superimposition read from the frame memory Image data is preferably provided to the light modulation means.
[0016]
In this projection display device, the superimposed image data in which the extracted image is superimposed on the input original image is written in the frame memory. Therefore, the superimposed image can be obtained by reading the superimposed image data from the frame memory.
[0017]
In the projection display apparatus, the image superimposing unit has a memory area including at least an area corresponding to all pixels of the light modulation unit, and stores the input second image data. And a combining unit that generates the superimposed image data by combining the second image data read from the frame memory and the extracted image data read from the extracted image memory. The superimposed image data synthesized by the synthesis unit may be given to the light modulation means.
[0018]
This projection display apparatus can also obtain superimposed image data and has the same operations and effects as the above projection display apparatus. However, in contrast to the above projection display device that reads and displays the superimposed image data from the frame memory, the projection display device superimposes the extracted image while reading the image data written in the frame memory. The time from the command for superimposing the image to the display of the superimposed image can be further shortened.
[0019]
In the projection display device, the combining unit may select a data selector for creating the superimposed image data by selecting one of the second image data and the extracted image data for each pixel. It is preferable to provide.
[0020]
In this projection display device, since the data selector selects either image data or extracted image data, the extracted image is superimposed on the original image by replacing part of the image data with the extracted image data. Can do.
[0021]
In the projection display apparatus, the combining unit may multiply the second image data and the extracted image data by a coefficient for each pixel, and the multiplication unit may multiply the second image data and the extracted image data. You may make it provide the addition part for adding 2nd image data and the said extraction image data for every pixel.
[0022]
In this projection display apparatus as well, the ratio of the density (luminance) between the decoration effect image and the original image can be adjusted by appropriately setting the coefficient.
[0023]
In the projection display apparatus, the synthesis unit controls the coefficient in the multiplication unit, thereby changing a synthesis ratio of the second image data and the extracted image data and superimposing the original image on the original image. It is preferable to provide a coefficient setting unit that adjusts the transparency of the extracted image.
[0024]
In this way, by controlling the coefficient of the multiplication unit, the synthesis ratio between the image data and the extracted image data can be changed, so that a superimposed image that transmits the portion where the extracted image is superimposed can be obtained.
[0025]
Further, in the projection display device, the coefficient setting unit changes the composite ratio of the second image data and the extracted image data by changing the coefficient in the multiplication unit with time, thereby changing the original image. It is preferable to change the transparency of the extracted image superimposed on the image with time.
[0026]
In this way, by changing the coefficient of the multiplication unit with time, the transparency of the portion where the extracted image is superimposed can be changed with time.
[0027]
A projection display device according to a second aspect of the present invention includes a frame memory that stores an image to be displayed as image data, and an image display signal generation that generates an image display signal based on the image data stored in the frame memory. And an electro-optical device that emits light that forms an image in response to the image display signal, and a projection optical system that projects the light emitted by the electro-optical device, and an image input from the outside An image extraction unit that extracts at least a part of an extraction target image arbitrarily selected from the above, an extraction image memory that stores extraction image data representing the extraction image, and the extraction image in a specific display condition A specific image display control unit configured to display a specific image represented by the specific image data including the extracted image data stored in a memory on a display screen, That.
[0028]
According to the projection display device, at least a part of an arbitrarily selected extraction target image can be extracted as an extracted image. Accordingly, a specific image including an extracted image arbitrarily extracted can be displayed in place of an image input to the projection display device under a specific display condition, and even when the specific image is not supplied from the outside. The desired specific image can be displayed.
[0029]
In the projection display device, the image extraction unit displays an extraction image setting screen for setting at least an extraction region and a display magnification as an extraction condition for extracting the extracted image, and extraction for setting the extraction region. When an area designation image is displayed in an overlapped manner with the extraction target image and a portion to be extracted using the extraction area designation image is set as the extraction area, a selection extraction representing a selection extraction image corresponding to the set extraction area When image data is written in the frame memory and the display magnification is set, the selected extracted image data is enlarged or reduced at the set display magnification, and the enlarged or reduced selected extracted image data is written in the frame memory. When the desired display magnification is determined, the selected drawing that has been enlarged or reduced at the desired display magnification. It is preferable to store image data of the extracted image memory.
[0030]
According to the above configuration, the extraction region of the extraction target image can be easily set by the extraction region designation image. Further, since the selected extracted image corresponding to the set extraction area can be displayed at the selected display magnification before the desired display magnification is determined, it can be determined while confirming the desired display magnification.
[0031]
Here, the image extraction unit displays a predetermined extraction frame as the extraction region designation image, and the predetermined extraction frame is provided inside the first black line frame and the first black line frame. It is preferable that an area between the first black line frame and the second black line frame is a white image.
[0032]
If it does as mentioned above, since an extraction area can be discriminated with respect to arbitrary extraction object images, an extraction area can be set up easily. In addition, the black line frame or the white image frame can be displayed without the extraction frame being buried in the extraction target image of any color or color scheme.
[0033]
In the projection display device, the extracted image memory stores a plurality of types of extracted image data representing a plurality of types of extracted images, and the specific image display control unit is configured to extract the plurality of types of extraction images under the specific display condition. A specific image including at least one extracted image selected from the images may be displayed on the display screen.
[0034]
The specific image display control unit may select at least two extracted images from the plurality of extracted images and display them in order.
[0035]
According to the above, it is possible to select an arbitrary image from a plurality of types of extracted images prepared in advance and display a more effective specific image.
[0036]
Each of the projection display devices further includes an operation condition determination unit that determines a specific operation condition in the projection display device, and the specific image display control unit is configured to perform the operation according to the specific operation condition in the operation condition determination unit. It is preferable to display the specific image on the display screen when it is detected.
[0037]
According to the above configuration, it is possible to automatically determine when the projection display device is in a specific operating condition and display a specific image including the extracted image extracted by the image extracting unit on the display screen. .
[0038]
Here, the operation condition determination unit is configured such that the image signal input to the projection display device is in a no-input state and the projection display device is in a state within a predetermined period after startup. It is preferable to detect at least one of the specific operating conditions.
[0039]
In this way, when the image data input to the projection display device as a specific operating condition is in a no-input state or because the projection display device is in a predetermined period after startup, When the image cannot be projected and displayed, the specific image including the extracted image extracted by the image extracting unit can be automatically displayed.
[0040]
A projection display device according to a third aspect of the present invention includes a frame memory that stores an image to be displayed as image data, and an image display signal generation that generates an image display signal based on the image data stored in the frame memory. A projection optical system that projects light emitted from the electro-optical device, and an electro-optical device that emits light that forms an image according to the image display signal. An operation condition determination unit that determines a specific operation condition, and a specific image that displays a specific image represented by specific image data on a display screen when the operation condition determination unit detects that the specific operation condition is satisfied And a display control unit.
[0041]
According to the above configuration, it is possible to automatically determine when the projection display device is in a specific operating condition and display a specific image on the display screen.
[0042]
Here, the operation condition determination unit is configured such that the image signal input to the projection display device is in a no-input state and the projection display device is in a state within a predetermined period after startup. It is preferable to detect at least one of the specific operating conditions.
[0043]
In this way, normal projection display cannot be performed when the image signal input to the projection display device is in a no-input state or because the projection display device is in a predetermined period after startup. In such a case, the specific image including the extracted image extracted by the image extracting unit can be automatically displayed.
[0044]
An image display device according to a fourth aspect of the present invention includes a frame memory that stores an image to be displayed as image data, and an image display signal generation unit that generates an image display signal based on the image data stored in the frame memory. An electro-optical device that emits light that forms an image in accordance with the image display signal, and extracts at least a part of an extraction target image arbitrarily selected from displayed images input from the outside A specific image represented by the specific image data including the extracted image data stored in the extracted image memory under a specific display condition. And a specific image display control unit that displays the image on the display screen.
[0045]
This image display device has the same operations and effects as the projection display device according to the second aspect, and instead of an image input to the image display device under specific display conditions selected by the user. The specific image including the extracted image arbitrarily extracted can be displayed.
[0046]
An image display device according to a fifth aspect of the present invention includes a frame memory that stores an image to be displayed as image data, and an image display signal generation unit that generates an image display signal based on the image data stored in the frame memory. An electro-optical device that emits light that forms an image according to the image display signal, and further includes an operation condition determination unit that determines a specific operation condition in the projection display device, and the operation condition determination unit And a specific image display control unit that displays a specific image represented by the specific image data on a display screen when the specific operation condition is detected.
[0047]
This image display device has the same operations and effects as the projection display device according to the third aspect, and automatically determines when the image display device is in a specific operating condition, The specific image can be displayed on the display screen.
[0048]
An image display method according to a sixth aspect of the present invention uses a projection display device provided with light modulation means, and projects and displays an image on a screen in accordance with image data input to the projection display device. A method of extracting at least a part of the input first image data as an extracted image, a step of preparing extracted image data representing the extracted image, and the input second image data Generating superimposed image data in which the original image and the extracted image are superimposed by superimposing the original image represented and the extracted image; and the light modulation for each pixel in accordance with the superimposed image data And a step of projecting the superimposed image obtained by driving the light modulating unit onto the screen.
[0049]
This display method has the same operation and effect as the projection display device according to the first aspect, and can simultaneously display related portions of images for a plurality of pages.
[0050]
An image display method according to a seventh aspect of the present invention is a method of displaying a specific image on a display screen using a projection display device, and extracting at least a part of an input extraction target image as an extracted image. A step of preparing extracted image data representing the extracted image, and a step of displaying an image represented by the image data including the extracted image data on the display screen as the specific image under a specific display condition. It is characterized by that.
[0051]
This display method has the same operation and effect as the projection display device according to the second aspect, and can display a desired specific image even when the specific image is not supplied from the outside.
[0052]
An image display method according to an eighth aspect of the present invention is a method of displaying a specific image on a display screen using a projection display device, the step of determining a specific operating condition in the projection display device; A step of displaying a specific image represented by the specific image data on a display screen by writing the specific image data in a frame memory when it is detected that the specific operation condition is detected in the step. Features.
[0053]
This display method has the same operation and effect as the projection display device according to the third aspect, and automatically determines when the projection display device is in a specific operating condition. The specific image can be displayed on the display screen.
[0054]
The present invention is also directed to a recording medium on which a computer program for causing a computer to execute at least a part of functions of each step or each part of the above invention is recorded. Recording media include flexible disks, CD-ROMs, magneto-optical disks, punched cards, printed matter on which codes such as bar codes are printed, computer internal storage devices (memory such as RAM and ROM) and external storage devices, A variety of computer-readable media can be used.
[0055]
BEST MODE FOR CARRYING OUT THE INVENTION
A. First embodiment
Next, embodiments of the present invention will be described based on examples. FIG. 1 is a block diagram showing the overall configuration of a projection display apparatus as a first embodiment according to the first aspect of the present invention. The projection display device in this embodiment includes a video signal conversion circuit 10, an extracted image superimposing circuit 12, a liquid crystal display driving circuit 14, a liquid crystal display panel 16, a frame memory 22, an extracted image memory 24, and an extracted image. A bitmap memory 26, a remote controller 28, a CPU 20, an illumination optical system 100, and a projection optical system 102 are provided. The video signal conversion circuit 10, the extracted image superimposing circuit 12, the extracted image memory 24, the remote controller control unit 28, and the CPU 20 are connected to each other via the bus 1. Further, the liquid crystal display driving circuit 14 is also connected to the bus 1, but the connection is omitted in FIG. The liquid crystal display panel 16 is illuminated almost uniformly by the illumination optical system 100, and an image displayed on the liquid crystal display panel 16 is projected onto the projection screen 104 by the projection optical system 102. In FIG. 1, the optical systems 100 and 102 are simplified.
[0056]
The video signal conversion circuit 10 is a circuit for AD-converting the input analog image signal AV1 and writing the AD-converted image data to the frame memory 22 or reading the image data from the frame memory 22. As the analog image signal AV1, for example, an image signal such as an RGB signal S1 representing a computer screen output from a personal computer or a composite image signal S2 representing a moving image output from a video recorder or a television is supplied.
[0057]
FIG. 2 is a block diagram showing the internal configuration of the video signal conversion circuit 10. The video signal conversion circuit 10 includes a synchronization separation unit 30, an AD conversion unit 32, and a video processor 34.
[0058]
When the input analog image signal AV1 is the composite image signal S2, the synchronization separation unit 230 separates the composite image signal S2 into the synchronization signal WSYNC and the component image signal S3 (analog image signal not including the synchronization signal). And output. The component image signal S3 is composed of three color signals representing three color RGB images. When the input analog image signal AV1 is the RGB signal S1, the synchronization signal is input separately, so that it is not necessary to use the synchronization separation unit 230.
[0059]
The AD conversion unit 232 converts the RGB signal S1 or the component image signal (RGB signal) S3 output from the synchronization separation unit 230 into image data for each color signal by a plurality of AD converters (not shown) in the AD conversion unit 232. It is a circuit for converting to DV1. Note that the timing of AD conversion in the plurality of AD converters is controlled by a dot clock DCLK generated inside the video processor 234 based on the synchronization signal WSYNC.
[0060]
The video processor 34 is a microprocessor for performing image data writing control and reading control on the frame memory 22. The image data DV1 output from the AD conversion unit 32 is once written in the frame memory 22, and is read from the frame memory 22 as necessary.
[0061]
FIG. 3 is a block diagram illustrating an example of the internal configuration of the video processor 34. The video processor 34 includes a writing control unit 70, a reading control unit 72, and an image extraction unit 74.
[0062]
The write control unit 70 and the read control unit 72 generate addresses ADD1 and ADD2 and control signals CTR1 and CTR2 when image data is written to or read from the frame memory 22, and supply the frame memory 22 with the addresses. Have The image data is written into the frame memory 22 in accordance with the address ADD1 and control signal CTR1 generated by the writing control unit 70. The image data written in the frame memory 22 is read in accordance with the address ADD2 and the control signal CTR2 generated by the read control unit 72. These addresses and control signals are generated based on a synchronization signal (WSYNC or RSYNC).
[0063]
Note that the writing of the image data to the frame memory 22 is performed in synchronization with the synchronization signal WSYNC. Further, the reading of the image data from the frame memory 22 and the processing in the subsequent circuit of the image data DV2 output from the video processor 34 are performed on the synchronization signal RSYNC output from the liquid crystal display driving circuit 14 (FIG. 1) described later. Done synchronously. Note that the first synchronization signal WSYNC and the second synchronization signal RSYNC are asynchronous with each other. Of course, as the first synchronization signal WSYNC and the second synchronization signal RSYNC, signals synchronized with each other can be used.
[0064]
The image extraction unit 74 (FIG. 3) has a function of extracting data of a specified portion in the image data when the image data written in the frame memory 22 is read. In addition, the image extraction unit 74 has a function of compressing the extracted image data and writing it to the extracted image memory 24 via the bus 1. Note that the image extraction unit 74 may not compress the extracted image data. Further, the extracted image data may be reduced instead of being compressed. Note that the cutout portion in the image data can be designated by the remote controller 29 described later. By specifying a cutout portion in the image data with the remote controller 29, the CPU 20 outputs an extraction address SADD corresponding to the cutout portion, and the image extraction unit 74 and the address output from the read control unit 72 are output. Based on the ADD2, pixel data of the cutout portion is extracted. Thereby, it is possible to extract only the pixel data for the designated portion.
[0065]
The extracted image memory 24 shown in FIG. 1 is a memory for storing the extracted image data extracted by the image extracting unit 74 (FIG. 3) in the video processor 34. In this embodiment, the extracted image data is compressed and stored in the extracted image memory 24 as extracted image compressed data CPD. The extracted image bitmap data BMD1 obtained by expanding the extracted image compressed data CPD is stored in the extracted image bitmap memory 26. Note that the extracted image data extracted may be stored in the extracted image bitmap memory 26 without being compressed. At this time, the extracted image memory 24 is unnecessary.
[0066]
FIG. 4 is an explanatory diagram showing the frame memory 22, the extracted image memory 24, and the extracted image bitmap memory 26 in the present embodiment. 4A and 4D show the memory space inside the frame memory 22. FIG. 4B shows a memory space inside the extracted image memory 24. FIG. 4C shows a memory space inside the extracted image bitmap memory 26.
[0067]
In the frame memory 22 shown in FIG. 4 (a), input image data for one frame (flower figure) is stored in a bitmap format. A portion surrounded by a broken line in FIG. 4A is designated as a cut-out portion by the user, and is extracted by the image extraction unit 74 (FIG. 3). The extracted extracted image data is compressed by the image extraction unit 74 and stored in the extracted image memory 24 as extracted image compressed data CPD.
[0068]
A plurality of types of extracted image compressed data CPD are stored in the extracted image memory 24 shown in FIG. 4B, and a program for expanding the extracted image compressed data CPD in a bitmap format is stored. Yes. In FIG. 4B, the program is stored after the address “0000” in the memory space of the extracted image memory 24, and the compressed data A, B, C are address “0A00”, “0B00”, Stored after “0C00”.
[0069]
In the extracted image bitmap memory 26 shown in FIG. 4C, the extracted image bitmap data BMD1 developed in the bitmap format by the program in the extracted image memory 24, the superimposed position of the extracted image on the input image data, and Coordinate data PD indicating the overlapping range is stored. The extracted image bitmap data BMD1 shown in FIG. 4C is expanded after the address “0000” in the memory space of the extracted image bitmap memory 26. The coordinate data PD is stored after the address “AAAA” and includes two points of coordinates (x1, y1), (x2, y2). The first coordinates (x1, y1) indicate the superimposed position of the extracted image in the image data, and the two images (x1, y1), (x2, y2) have a superimposed range (size) of the extracted image. Is shown.
[0070]
Also, in the frame memory 22 shown in FIG. 4D, image data (a tree figure) for superimposing the extracted image shown in FIG. 4C is stored in a bitmap format. The coordinates (x1, y1) and (x2, y2) shown in FIG. 4D are values when the address “0000” in the frame memory 22 is set to the coordinates (0, 0). The coordinates (x1, y1) and (x2, y2) correspond to the coordinate data PD shown in FIG. The upper left point a of the extracted image bitmap data BMD1 shown in FIG. 4C corresponds to the coordinates (x1, y1), and the lower right point b corresponds to the coordinates (x2, y2).
[0071]
The extracted image bitmap data BMD1 is developed when the user designates an arbitrary type from among a plurality of types of extracted images prepared by cutting out image data in advance. The coordinate data PD is obtained by the user specifying a superposition position in the image data, or a superposition position and a superposition range. When only the superposition position is designated, the coordinates (x1, y1) are determined, and the coordinate data (x2, y2) are determined by the size (size at the time of clipping) determined in advance by the type of the extracted image. The When both the superposition position and the superposition range are designated, the coordinates (x1, y1) are determined by designating the superposition position, and the coordinates (x2, y2) are designated by (x2 + Δx) by designating the superposition range (size). , Y2 + Δy). As a result, the extracted image can be enlarged or reduced to an arbitrary size. In this embodiment, the extracted image bitmap data BMD1 and the coordinate data PD are stored in the extracted image bitmap memory 26, but may be stored in the extracted image memory 24.
[0072]
The extracted image superimposing circuit 12 (FIG. 1) is a circuit for superimposing the input image and the extracted image. That is, the extracted image superimposing circuit 12 superimposes the image data DV2 output from the video signal conversion circuit 10 and the extracted image bitmap data BMD1 (FIG. 4C) developed in the extracted image bitmap memory 26. To do.
[0073]
FIG. 5 is a block diagram showing the internal configuration of the extracted image superimposing circuit 12. The extracted image superimposing circuit 12 includes two multiplication units 40 and 42, one addition unit 44, and a coefficient setting unit 46. A configuration including two multiplication units 40 and 42 and one addition unit 44 is provided for each color of RGB. The image data DV2 output from the video processor 34 is input to the first multiplier 40, and the extracted image bitmap data BMD1 developed in the extracted image bitmap memory 26 is input to the second multiplier 42.
[0074]
The coefficient setting unit 46 has a function of setting the coefficients k1 and k2 of the multiplication units 40 and 42. The coefficients k1 and k2 can be set to values from “0” to “1”, respectively, and are normally set so that the sum of k1 and k2 is “1”. The coefficients k1 and k2 are controlled by the coefficient setting unit 46 based on the coordinate data PD (FIG. 4C).
[0075]
The multipliers 40 and 42 are circuits for sequentially multiplying each pixel data of the image data input to each by a constant number. The image data DV2 is converted into a k1 times signal in the multiplier 40. Further, the extracted image bitmap data BMD1 is converted into a signal of k2 times in the multiplier 42. The image data DV3 and the extracted image bitmap data BMD2 converted and output by the multipliers 40 and 42 are input to the adder 44.
[0076]
The adder 44 is a circuit for sequentially adding pixel data of two input image signals. In the adding unit 44, the image data DV3 and the extracted image bitmap data BMD2 are added, and the superimposed image data DDV1 is output. Note that the multiplication units 40 and 42, the addition unit 44, and the coefficient setting unit 46 in the present embodiment correspond to the synthesis unit in the first aspect of the present invention.
[0077]
The superimposed image data DDV1 output from the extracted image superimposing circuit 12 is supplied to the liquid crystal display driving circuit 14 (FIG. 1). The liquid crystal display driving circuit 14 displays an image on which the extracted image is superimposed on the liquid crystal display panel 16 in accordance with the superimposed image data DDV1. The image displayed on the liquid crystal display panel 16 is projected on the projection screen 104 using the optical systems 100 and 102. That is, light incident on the liquid crystal display panel 16 by the illumination optical form 100 is modulated according to image data given to the liquid crystal display panel 16, and light emitted from the liquid crystal display panel 16 is projected onto the projection screen 104 by the projection optical system 102. Projected. Note that the liquid crystal display panel 16 in the present embodiment is the first generator.
It corresponds to a bright light modulation means.
[0078]
The remote control unit 28 (FIG. 1) controls the function of each unit of the projection display device based on a command from the remote control 29. What is controlled by the remote controller 28 is mainly processing relating to the extracted image. For example, the function of each unit based on commands from the remote controller 29 such as designation of a cutout portion in image data, selection of the type of extracted image to be superimposed, superimposed position of the extracted image, overlapping range, display / non-display of the extracted image, etc. To control.
[0079]
The functions of the video signal conversion circuit 10, the extracted image superimposing circuit 12, and the remote control unit 28 can be realized by a computer program instead of hardware. A computer program for realizing the functions of these units is provided in a form recorded on a computer-readable recording medium such as a floppy disk or a CD-ROM. The computer (projection display device) reads the computer program from the recording medium and transfers it to the internal storage device or the external storage device. Or you may make it supply a computer program to a computer from a program supply apparatus via a communication path. When realizing the functions of a computer, a computer program stored in an internal storage device is executed by a CPU (microprocessor) of the computer. The computer program recorded on the recording medium may be directly executed by the computer.
[0080]
In this specification, the computer is a concept including a hardware device and an operation system, and means a hardware device that operates under the control of the operation system. Further, when an operation system is unnecessary and a hardware device is operated by an application program alone, the hardware device itself corresponds to a computer. The hardware device includes at least a microprocessor such as a CPU and means for reading a computer program recorded on a recording medium. The computer program includes program code for causing such a computer to realize the functions of the above-described means. Note that some of the functions described above may be realized by an operation system instead of an application program.
[0081]
The “recording medium” in the present invention includes a flexible disk, a CD-ROM, a magneto-optical disk, an IC card, a ROM cartridge, a punch card, a printed matter on which a code such as a bar code is printed, an internal storage device (RAM) of a computer. And various media that can be read by a computer such as an external storage device.
[0082]
FIG. 6 is an explanatory diagram showing a superimposition process between the image data stored in the frame memory 22 and the extracted image bitmap data BMD1 stored in the extracted image bitmap memory 26. FIG. 6A shows a memory space in the frame memory 22 in which image data (document) is stored. FIG. 6B shows a memory space in the extracted image bitmap memory 26, in which extracted image bitmap data BMD1 (graph) is stored. Further, the extracted image bitmap memory 26 stores coordinate data PD indicating a superposition position and a superposition range. The two coordinates (x1, y1) and (x2, y2) of the coordinate data PD shown in FIG. 6B correspond to the coordinates (x1, y1) and (x2, y2) shown in FIG. Yes. FIG. 6C shows a superimposed image represented by the superimposed image data DDV1 in which the image data and the extracted image bitmap data BMD1 are superimposed.
[0083]
The superimposition of the image data and the extracted image bitmap data BMD1 is performed based on the coordinate data PD. Image data is sequentially input to the first multiplication unit 40 in the extracted image superimposing circuit 12 (FIG. 5), but the second multiplication unit 42 has a portion to be superimposed, that is, coordinates (x1, y1) and the like. Extracted image bitmap data BMD1 is input only within the range of (x2, y2). The timing at which the extracted image bitmap data BMD1 is input to the multiplication unit 42 is controlled by the CPU 20 based on the coordinate data PD. Simultaneously with the input of the extracted image bitmap data BMD1 to the multiplier 42, the coefficients k1 and k2 of the multipliers 40 and 42 are changed. That is, when the extracted image bitmap data BMD1 is not input to the multiplier 42, the coefficients k1 and k2 of the multipliers 40 and 42 are set to (1, 0), and the extracted image bitmap data BMD1 is stored in the multiplier 42. When input, the coefficients k1, k2 are set to (0, 1). As a result, for the pixels outside the range of the coordinate data (x1, y1) and (x2, y2), the image data (document) of the original image shown in FIG. Extracted image bitmap data BMD1 shown in FIG. 6B is output from the extracted image superimposing circuit 12 for pixels within the range of two coordinates (x1, y1), (x2, y2). In this manner, the image data and the extracted image bitmap data BMD1 are superimposed to generate superimposed image data DDV1 representing the superimposed image in FIG. 6C.
[0084]
The extracted image may be developed in the extracted image bitmap memory 26 so as to correspond to the superimposed position in the image data. FIG. 7 is an explanatory diagram showing the extracted image bitmap data BMD1 developed in the extracted image bitmap memory 26. As shown in FIG. In the extracted image bitmap memory 26 shown in FIG. 7, a memory capacity corresponding to one frame of image data is allocated to the extracted image bitmap data BMD1, and the extracted image has coordinates (x1, y1), (x2, y2). ). When the image data is expanded as shown in FIG. 7, the pixel data corresponding to the same position in the image of the image data and the extracted image bitmap data BMD1 are simultaneously input to the multipliers 40 and 42, respectively. . At this time, outside the range of the coordinates (x1, y1) and (x2, y2) of the coordinate data PD, the coefficient (k1, k2) is set to (1, 0), and the coordinates (x1, y1) and (x2) are set. , Y2), the coefficient (k1, k2) is set to (0, 1). Even in this way, the superimposed image data DDV1 representing the superimposed image in FIG. 6C can be generated by superimposing the image data and the extracted image bitmap data BMD1.
[0085]
As described above, when the extracted image is expanded as shown in FIG. 7, a memory capacity for one frame is required as a storage area for the extracted image bitmap data BMD1, but as shown in FIG. In the case of developing in such a manner, it is only necessary to have a memory capacity comparable to the size of the extracted image that has been bitmap-developed, and thus there is an advantage that the memory capacity may be small.
[0086]
FIG. 8 is an explanatory diagram showing an example of an image projected on the projection screen 104 when the extracted image is superimposed on the image input from the personal computer. In FIG. 8A, two extracted images (tree images) are superimposed on the input image (document). In FIG. 8B, two types of extracted images (yacht image and tree image) are superimposed on the input image (document). In FIG. 8C, the extracted image (yacht image) shown in FIG. 8B is enlarged and superimposed on the input image (document).
[0087]
The extracted images shown in FIGS. 8A and 8B are superimposed by specifying a superposition position in the projection image. At this time, the coordinate data PD is composed of coordinates (x1, y1) indicating the designated position and coordinates (x2, y2) determined by the size of each extracted image determined in advance. Further, the extracted image shown in FIG. 8C is superimposed by designating a superposition position and a superposition range in the projection image. At this time, the coordinate data PD is composed of preset coordinates (x1, y1) and coordinates (x2, y2) corresponding to the designated size.
[0088]
Note that the extracted image bitmap data BMD1 includes coordinate data PD indicating the superimposed position in the original image, so that the extracted image can be displayed at an arbitrary position designated by the remote controller 29. Since the contents of the extracted image bitmap data BMD1 and the coordinate data PD are always updated in synchronization with the synchronization signal RSYNC, the extracted image is real-time at any position in the projected image by operating the remote controller 29. It can be moved with. Furthermore, as shown in FIG. 8B, a plurality of extracted images of any type can be displayed simultaneously. Note that the extracted image bitmap data BMD1 is generated by the remote controller control unit 28 that has received a command from the remote controller 29 executing a program stored in the extracted image memory 24.
[0089]
Further, the shape of the extracted image extracted by the image extracting unit 74 is not limited to a quadrangle as shown in FIG. That is, the image extraction unit 74 can extract a portion designated by the remote controller 29 from the original image, and thus it is possible to obtain extracted images of various shapes such as an ellipse, a circle, a star, and a figure surrounded by a free line. it can.
[0090]
FIG. 9 is an explanatory diagram illustrating an example of an image projected on the projection screen 104 when an extracted image is superimposed on an image input from a personal computer. In FIG. 9, an oval extracted image (yacht image) is superimposed on an input image (document).
[0091]
In the present embodiment, the coordinate data PD only includes the coordinates of two points indicating the superimposed position and range of the extracted image. Therefore, when the extracted image as shown in FIG. In the range designated by the coordinates, processing is performed so as not to superimpose a portion where no extracted image exists.
[0092]
FIG. 10 is an explanatory diagram showing the extracted image bitmap memory 26 when the extracted image shown in FIG. 9 is expanded. In the extracted image bitmap data BMD1 shown in FIG. 10, pixels in the hatched portion outside the ellipse are not superimposed on the input image, and therefore such pixels in the portion are configured with specific pixel data. ing. That is, for pixels for which no extracted image exists, pixel data that is not used, for example, pixel data in which all bits of RGB three-color pixel data are “0” may be developed. In this case, for example, the extracted image bitmap data BMD1 is input to the coefficient setting unit 46, and the coefficient setting unit 46 examines the extracted image bitmap data BMD1 to determine whether or not the extracted image is a pixel. To do. Then, when pixel data indicating that the extracted image does not exist is input, the coefficient (k1, k2) given to the multipliers 40, 42 may be changed to (1, 0). In this way, only the portion of the extracted image bitmap data BMD1 where the extracted image exists can be superimposed on the input image data. Of course, the coordinate data PD may be data composed of coordinates of a large number of points surrounding a portion where the extracted image exists. In this case, only the portion where the extracted image exists can be superimposed only by the coordinate data PD.
[0093]
In the examples shown in FIGS. 8 and 9, the extracted image appears to be painted on the input original image. At this time, a part of the input original image is replaced with the extracted image. That is, in the extracted image superimposing circuit 12 shown in FIG. 5, the coefficients (k1, k2) of the multipliers 40 and 42 are set to (1, 0) for the portion where the extracted image is not superimposed. For the portion where the extracted image is superimposed, the coefficient (k1, k2) is set to (0, 1).
[0094]
Further, by changing the coefficients k1 and k2 of the multipliers 40 and 42, it is possible to superimpose a transparent extracted image. For example, if both the coefficients k1 and k2 of the multipliers 40 and 42 are set to “½”, the input image appears to pass through the extracted image even in the portion where the extracted image is superimposed.
[0095]
FIG. 11 is an explanatory diagram showing an example of a projected image when a transparent extracted image is superimposed. FIG. 11A shows images (graph 1 and graph 2) input from a personal computer, and a portion surrounded by a broken line (graph 2) is designated as a cutout portion. FIG. 11B shows a superimposed image in which the extracted image (graph 2) is superimposed on the portion of the graph 1 of the input image shown in FIG. 11A. The input image (graph 1) is the extracted image (graph 2). ) Appears to be transparent. As described above, by setting the coefficients k1 and k2 of the multipliers 40 and 42 of the extracted image superimposing circuit 12 (FIG. 5) to “1/2”, the effect of superimposing the transparent extracted image is obtained. Can do.
[0096]
The superimposed images shown in FIG. 8, FIG. 9, and FIG. 11 are always obtained as constant values such as “0”, “1”, “1/2” for the coefficients k1, k2 of the multipliers 40, 42. However, the values of the coefficients k1 and k2 may be changed with time. For example, the coefficient (k1, k2) is first set to (0, 1) for the portion where the extracted image is superimposed, and gradually (0.1, 0.9), (0.2, 0.8) over time. ... (1,0) may be used. In this way, when the coefficients k1 and k2 are changed with time, the input image appears to be initially filled with the extracted image, but the transparent extracted image is gradually superimposed with time. Finally, it seems that the superimposed extracted image disappears. Such a superposition effect can be obtained by changing the coefficients k1 and k2 of the multipliers 40 and 42 with time. The change of the coefficient values is controlled by the coefficient setting unit 46 based on a command from the CPU 20.
[0097]
As can be seen from the above description, the extracted image superimposing circuit 12 and the frame memory 22 in this embodiment correspond to the image superimposing unit in the first aspect of the present invention. Further, the extracted image memory 24 and the extracted image bitmap memory 26 in this embodiment correspond to the extracted image memory in the first aspect of the present invention. One of the two memories 24 and 26 can be omitted.
[0098]
B. Second embodiment
FIG. 12 is a block diagram showing the overall configuration of a projection display apparatus as a second embodiment according to the first aspect of the present invention. The projection display device includes a video signal conversion circuit 60, a liquid crystal display driving circuit 14, a liquid crystal display panel 16, a frame memory 22, an extracted image memory 24, a remote controller 28, a CPU 20, and an illumination optical system. 100 and a projection optical system 102. The video signal conversion circuit 60, the extracted image memory 24, the remote control unit 28, and the CPU 20 are connected to each other via the bus 1. Further, the liquid crystal display driving circuit 14 is also connected to the bus 1, but the connection is omitted in FIG.
[0099]
The projection display device of the second embodiment does not include the extracted image superimposing circuit 12 and the extracted image bitmap memory 26 of FIG. 1 in the first embodiment. In the present embodiment, the video signal conversion circuit 60 has a function of superimposing the original image and the extracted image. The extracted image bitmap data BMD1 is stored in the extracted image memory 24. Therefore, the video signal conversion circuit 60 and the frame memory 22 in the present embodiment correspond to the image superimposing unit in the first aspect of the present invention. In this embodiment, only the extracted image memory 24 corresponds to the extracted image memory in the first aspect of the present invention.
[0100]
FIG. 13 is a block diagram showing the internal configuration of the video signal conversion circuit 60. The video signal conversion circuit 60 includes a synchronization separation unit 30, an AD conversion unit 32, and a video processor 62. Since the functions of the synchronization separation unit 30 and the AD conversion unit 32 are the same as those of the projection display device in the first embodiment, the description thereof is omitted.
[0101]
The video processor 62 is a microprocessor for controlling superimposition processing of input image data and extracted image bitmap data, and writing and reading of the superimposed image data on which the extracted image is superimposed on the frame memory 22. is there.
[0102]
The video processor 62 receives the image data DV1 output from the AD converter 32 and the extracted image bitmap data BMD1 developed in the extracted image memory 24 via the bus 1. Creation of the superimposed image data in the video processor 62 is performed by selecting the image data DV1 and the extracted image bitmap data BMD1 and writing them in the frame memory 22. Selection of the image data DV1 and the extracted image bitmap data BMD1 is performed by a data selector in the video processor 62.
[0103]
FIG. 14 is a block diagram illustrating an example of the internal configuration of the video processor 62. The video processor 34 includes a write control unit 70, a read control unit 72, an image extraction unit 74, and a data selector 76.
[0104]
The image extraction unit 74 (FIG. 14) has a function of extracting data of a portion designated as a cutout portion in the image data DV1 when the image data DV1 is input to the video processor 62. The image extraction unit 74 has a function of compressing the extracted image data and storing it in the extracted image memory 24 via the bus 1. Note that the image extraction unit 74 may not compress the extracted image data. Further, the extracted image data may be reduced instead of being compressed. The cutout part in the image data can be designated by the remote controller 29. By designating a cutout portion in the image data with the remote controller 29, the CPU 20 outputs a sampling signal SMP corresponding to the cutout portion, and the image extraction unit 74 extracts pixel data of the cutout portion based on the sampling signal SMP. . Thereby, it is possible to extract only the pixel data for the designated portion.
[0105]
The data selector 76 (FIG. 14) receives the image data DV1, the extracted image bitmap data BMD1 developed in the extracted image memory 24, and the selection signal SEL. The data selector 76 is provided for each color of RGB. The selection of the image data DV1 and the extracted image bitmap data BMD1 is performed for each pixel data and is controlled by the selection signal SEL. The data selector 76 selects and outputs either pixel data of the image data DV1 or the extracted image bitmap data BMD1 based on the selection signal SEL. Therefore, the data written in the frame memory 22 is superimposed image data in which the extracted image is superimposed on the input image. The selection signal SEL is generated by the CPU 20 based on the coordinate data PD.
[0106]
In the present embodiment, the superimposed image appears to be painted on the input image. This corresponds to the case where the coefficients (k1, k2) of the multipliers 40, 42 of the extracted image superimposing circuit 12 (FIG. 5) in the first embodiment are (0, 1) for the portion where the extracted image is superimposed. .
[0107]
Note that when the extracted image bitmap data BMD1 is expanded as shown in FIG. 6B, the data selector 76 is in the range of the coordinates (x1, y1) and (x2, y2) of the coordinate data PD. Extracted image bitmap data BMD1 is input only at. The timing at which the extracted image bitmap data BMD1 is input to the data selector 76 is controlled by the CPU 20 based on the synchronization signal WSYNC and the coordinate data PD. That is, the input timing of the extracted image bitmap data BMD1 is determined by obtaining the input timing of the pixel data of the image data DV1 corresponding to the superimposed position from the coordinate data PD of the extracted image bitmap data BMD1. Simultaneously with the input of the extracted image bitmap data BMD1, the extracted image bitmap data BMD1 is selected by the selection signal SEL. In this way, the selection of the image data DV1 and the extracted image bitmap data BMD1 can be performed for each pixel corresponding to the same position in the image.
[0108]
When the extracted image bitmap data BMD1 is expanded as shown in FIG. 7, pixel data corresponding to the same position in the image of the image data DV1 and the extracted image bitmap data BMD1 is simultaneously input to the data selector 76. Entered. The designation of the pixel data to be input is performed based on the synchronization signal WSYNC. That is, by reading the extracted image bitmap data BMD1 from the extracted image memory 24 in synchronization with the image data DV1 input to the video processor 62, the pixel data at the same position in the image can be associated. Further, by supplying the selection signal SEL to the data selector 76 based on the coordinate data PD, the extracted image can be superimposed on the input image.
[0109]
The writing control unit 70 and the reading control unit 72 generate addresses ADD1 and ADD2 and control signals CTR1 and CTR2 when the superimposed image data is written to or read from the frame memory 22, and supply the frame memory 22 with the addresses. It has a function. The superimposed image data is written into the frame memory 22 in accordance with the address ADD1 and the control signal CTR1 generated by the writing control unit 70. The superimposed image data written in the frame memory 22 is read according to the address ADD2 and the control signal CTR2 generated by the read control unit 72. These addresses and control signals are generated based on a synchronization signal (WSYNC or RSYNC).
[0110]
Note that the writing of the superimposed image data to the frame memory 22 is performed in synchronization with the synchronization signal WSYNC. The readout of the superimposed image data from the frame memory 22 is performed in synchronization with the synchronization signal RSYNC output from the liquid crystal display driving circuit 14 (FIG. 12). Note that the first synchronization signal WSYNC and the second synchronization signal RSYNC are asynchronous with each other. Of course, as the first synchronization signal WSYNC and the second synchronization signal RSYNC, signals synchronized with each other can be used.
[0111]
In the present embodiment, as described above, the superimposed image data is obtained by directly writing to the frame memory 22. The superimposed image data written in the frame memory 22 is read out by the video processor 62.
[0112]
The superimposed image data DDV2 output from the video signal conversion circuit 60 (FIG. 12) is supplied to the liquid crystal display drive circuit 14 (FIG. 12). The liquid crystal display driving circuit 14 displays an image on which the extracted image is superimposed on the liquid crystal display panel 16 according to the superimposed image data DDV2. The image displayed on the liquid crystal display panel 16 is projected on the projection screen 104 using the optical systems 100 and 102.
[0113]
As described above, in the first and second embodiments, at least a part of the input image can be extracted as an extracted image in the projection display device, and thus the extracted image cut out from the other image into the input image. Can be superimposed. Therefore, it is possible to extract an extracted image not only for an image signal from a personal computer but also for an image signal input from a video recorder or a television and superimpose it on the input image. Further, the extracted image can be superimposed at an arbitrary position in the input image by the coordinate data PD, and the extracted image can be superimposed by being enlarged or reduced.
[0114]
C. Third embodiment:
Next, an embodiment according to the second aspect of the present invention will be described based on examples.
[0115]
C-1. Overall configuration and operation of the projection display device:
FIG. 15 is a block diagram showing the overall configuration of a projection display apparatus as an embodiment according to the second aspect of the present invention. The projection display device in this embodiment includes a video signal processing circuit 210, an on-screen display (OSD) controller 212, an OSD memory 213, a liquid crystal light valve driving circuit 214, a liquid crystal light valve 216, and a frame memory 222. , An extracted image memory 224, a remote controller 28, a CPU 20, an illumination optical system 100, and a projection optical system 102. The video signal processing circuit 210, the OSD controller 212, the extracted image memory 224, the remote controller control unit 28, and the CPU 20 are connected to each other via the bus 1.
[0116]
The video signal processing circuit 210 is a circuit for AD-converting the input analog image signal AV1 and writing the AD-converted image data into the frame memory 222 and reading the image data from the frame memory 222. As the analog image signal AV1, for example, an image signal such as an RGB signal S1 representing a computer screen output from a personal computer or a composite image signal S2 representing a moving image output from a video recorder or a television receiver is supplied. Is done.
[0117]
FIG. 16 is a block diagram showing an internal configuration of the video signal processing circuit 210. The video signal processing circuit 210 includes a synchronization separation unit 230, an AD conversion unit 232, and a video processor 234. The synchronization separation unit 230 and the AD conversion unit 232 according to the present embodiment have the same functions as the synchronization separation unit 30 and the AD conversion unit 32 according to the first embodiment (FIG. 2), and thus detailed description thereof is omitted. To do.
[0118]
The video processor 234 is a circuit (microprocessor) for performing various image processing such as image data writing control and reading control to the frame memory 222 and extraction image data writing control and reading control to the extraction image memory 224. It is. The video processor 234 receives the image data DV1 output from the AD conversion unit 232. In addition, the video processor 234 receives specific image data (hereinafter referred to as “specific image data”) including the extracted image data CPD1 stored in the extracted image memory 224 and the background image BGD1 generated by the CPU 20. 1 is input.
[0119]
FIG. 17 is a block diagram illustrating an example of the internal configuration of the video processor 234. The video processor 234 includes a write control unit 270, a read control unit 272, an extraction control unit 274, and a data selector 276. The write control unit 270 and the read control unit 272 according to the present embodiment have the same functions as the write control unit 70 and the read control unit 72 according to the first embodiment (FIG. 3), and thus will be described in detail. Is omitted.
[0120]
The data selector 276 receives the image data DV1, the extracted image data BMD1 stored in the extracted image memory 224, and the specific image data SPD1 including the background image data BGD generated by the CPU 20, and the selection signal SEL is input to the data selector 276. Have been entered. The data selector 276 is provided for each color of RGB. The selection between the image data DV1 and the specific image data SPD1 is controlled by the selection signal SEL depending on whether the “normal image display mode” or the “specific image display mode” is selected. These modes will be described later. The data selector 276 selects and outputs either the image data DV1 or the specific image data SPD1 based on the selection signal SEL. Therefore, the frame memory 222 stores either the input image data DV1 or the specific image data SPD1 depending on whether the normal display mode or the specific image display mode is selected. The selection signal SEL is generated by the CPU 20 when the user selects it using a remote controller 29 described later.
[0121]
Note that image data is written to the frame memory 222 in synchronization with the synchronization signal WSYNC when the image data to be written is the input image data DV1. On the other hand, when the image data to be written is the specific image data SPD1, it is performed in accordance with a control signal supplied from the CPU 20 to the write control unit 270 via the bus 1. Further, in the reading of the image data from the frame memory 222 and the processing in the subsequent circuit of the image data DV2 output from the video processor 234, the liquid crystal light valve driving circuit 214 (FIG. 15) described later drives the liquid crystal light valve 216. This is performed in synchronization with the optimum synchronization signal RSYNC. The synchronization signal RSYNC is generated by a synchronization signal generation circuit (not shown) provided in the video processor 234. Note that the first synchronization signal WSYNC and the second synchronization signal RSYNC are asynchronous with each other. Of course, it is also possible to use signals that are synchronized with each other as the first synchronization signal WSYNC and the second synchronization signal RSYNC. Note that the synchronization signal generation circuit is not necessarily provided in the video processor 234. For example, the liquid crystal light valve drive circuit 214 may be provided. Moreover, you may make it prepare independently.
[0122]
The extraction control unit 274 has a function of extracting data of a designated portion in image data designated as described later when the image data written in the frame memory 222 is read. Further, the extraction control unit 274 has a function of enlarging / reducing the extracted image data based on the image enlargement / reduction ratio set as described later. The extraction control unit 274 has a function of writing the extracted image data CPD1 to the extracted image memory 224 via the bus 1. Note that the cutout portion (extraction region) in the image data can be designated by the remote controller 29 described later. By specifying the cutout portion in the image data with the remote controller 29, the CPU 20 outputs the extraction address SADD corresponding to the cutout portion, and the extraction control unit 274 outputs the extraction address SADD and the address output from the read control unit 272. The image data of the cutout portion is extracted based on ADD2. Thereby, only the image data for the designated portion can be extracted.
[0123]
The image data DV1 or specific image data SPD1 stored in the frame memory 222 is read from the frame memory in synchronization with the synchronization signal RSYNC, and the image data DV2 is output from the video processor 234.
[0124]
The extracted image memory 224 shown in FIG. 15 is a memory for storing the extracted image data CPD1 extracted by the extraction control unit 274 (FIG. 17) in the video processor 234. The extracted image data CPD1 is stored in the extracted image memory 224 in a predetermined format. The predetermined format is not particularly limited, and may be a predetermined format. For example, the extracted image data CPD1 may be compressed data or bitmap data. When the extracted image data CPD 1 is compressed data, the extracted image data CPD 1 is compressed by the CPU 20 or the extraction control unit 274 when written to the extracted image memory 224 and written to the extracted image memory 224. Further, when being read out from the extracted image memory 224, it is expanded by the CPU 20 or the extraction control unit 274.
[0125]
FIG. 18 is an explanatory diagram showing the extracted image memory 224. One extracted image data is stored in the extracted image memory 224. In this stored data, an information ID indicating the contents of the extracted image data and the extracted image data CPD1 are stored. Note that the extracted image memory 224 can store not only one type but also a plurality of types of stored data.
[0126]
The OSD controller 212 shown in FIG. 15 is an OSD that represents a menu screen, a pointer image, or the like for controlling the functions of the respective units of the projection display device based on a command from the remote controller 29 supplied via the remote control unit 28. Generate image data. In the OSD memory 213, image data of a pointer image, graphic data constituting a menu screen, font data, and the like are stored in a predetermined format. When displaying a menu screen, a pointer image, or the like, the OSD controller 212 reads the corresponding image data from the OSD memory 213 and generates OSD image data. The OSD controller 212 combines the OSD image data with the image data DV2 output from the video signal processing circuit 210. The OSD controller 212 can combine the image data DV2 and the OSD image data by providing the OSD controller 212 with a selector circuit (not shown). Alternatively, the image data DV2 and the OSD image data can each be provided with two multipliers that multiply each by a predetermined value and an adder that adds the two multiplication results. Note that an image (extraction region designation image) for designating a cutout portion in the image data is generated by the OSD controller 212.
[0127]
The image data DV3 output from the OSD controller 212 is supplied to the liquid crystal light valve driving circuit 214. The liquid crystal light valve driving circuit 214 modulates the illumination light of the illumination optical system 100 via the liquid crystal light valve 216 according to the image data DV3. The illumination light modulated by the liquid crystal light valve 216 is projected onto the projection screen 104 by the projection optical system 102, and an image is displayed on the projection screen 104. The liquid crystal light valve 216 in this embodiment corresponds to the electro-optical device in the second aspect of the present invention, and the liquid crystal light valve drive circuit 214 corresponds to the image display signal generation unit. The “projection optical system” of the present invention includes not only a narrowly defined projection optical system but also a broadly defined projection optical system including an illumination optical system. The liquid crystal light valve drive circuit 214 may be formed on the substrate of the liquid crystal light valve 216 that is an electro-optical device, and the two may be integrated.
[0128]
Note that an enlargement / reduction processing circuit (not shown) is provided between the OSD controller 212 and the liquid crystal light valve drive circuit 214 so that the image data DV3 output from the OSD controller 212 is reduced or enlarged and displayed. Good.
[0129]
The remote control control unit 28 (FIG. 15) controls functions of each unit of the projection display device based on a command from the remote control 29. What is controlled by the remote controller 28 is mainly processing relating to the extracted image. For example, the function of each unit is controlled based on a command from the remote controller 29 such as designation of a cutout portion in image data and display / non-display of an extracted image.
[0130]
The functions of the video signal processing circuit 210, the OSD controller, and the remote control unit 28 can be realized not only by hardware but also by a computer program.
[0131]
In the projection display device configured as described above, when the user normally selects the normal image display mode with the remote controller 29, the analog image signal AV1 input from the outside to the video signal processing circuit 210 is shown. Digital image data DV1 is stored in the frame memory 222, and an image represented by the image data DV1 can be displayed on the projection screen 104. FIG. 19 shows an example in which an image input from the outside is displayed on the projection screen 104. When the user selects the specific image display mode using the remote controller 29, the background image BGD1 generated by the CPU 20 or the extracted image data CPD1 stored in the extracted image memory 224 is used as the specific image data SPD1 in the frame memory 222. The specific image represented by the specific image data SPD1 stored in the frame memory 222 can be displayed on the projection screen 104. FIG. 20 shows an example in which a specific image represented by specific image data SPD 1 including extracted image data CPD 1 and background image data BGD 1 stored in the extracted image memory 224 is displayed on the projection screen 104.
[0132]
When the user selects the specific image display mode, an extracted image that is to be displayed as the specific image can be selected from a plurality of types of extracted images stored in the extracted image memory 224. . It is also possible to select several extracted images in order from a plurality of types of extracted images stored in the extracted image memory 224 and repeatedly display these extracted images in order. FIG. 21 shows an example in which extracted images represented by three types of extracted image data CPD1 (A), CPD1 (B), and CPD1 (C) are sequentially selected and displayed on the projection screen 104.
[0133]
In the above-mentioned projection display device, a company prepared in advance instead of the image used for the presentation in the case of a question-and-answer session or when it takes some time to display a new projected image. It is possible to enhance the presentation effect by displaying a logo mark or product image (specific image).
[0134]
The extracted image data CPD1 stored in the extracted image memory 224 can be extracted as described below.
[0135]
C-2. Extraction of extracted images:
22 to 27 are explanatory diagrams showing a procedure for cutting out an extracted image (a character string “USER LOGO”) from an image input to the projection display device. Each of FIGS. 22 to 27 shows an image displayed on the projection screen 104.
[0136]
When a “menu key” (not shown) on the remote controller 29 is pressed, a menu screen is displayed by the OSD controller 212 (FIG. 15). When “image extraction setting” is selected from the menu screen and the “enter key” on the remote controller 29 is pressed, the extracted image setting mode is started. Hereinafter, selecting a word, an area, or the like on the screen with the remote control 29 as described above and pressing the “decision key” on the remote control 29 is referred to as “selection and determination”. When the extracted image setting mode is started, writing to the frame memory 222 is stopped. This stop may be performed in response to the start of the extracted image setting mode. When a moving image is displayed, the user may select and stop using the remote control 29.
[0137]
When writing to the frame memory 222 is stopped, the image stored in the frame memory 222 at that time is displayed on the screen 104 as shown in FIG. Further, the OSD controller 212 displays an image extraction setting screen. The image extraction setting screen displays “Do you want to use a part of this image as an extracted image?” And determines whether to extract an image from the currently displayed image. This selected and determined image is referred to as an extraction target image. If “No” is selected and determined, the extracted image setting mode is terminated and the menu screen is displayed. When “Yes” is selected and determined, a selection frame WF for selecting an extracted image is displayed by the OSD controller 212 as shown in FIG. The display frame WF is a frame having a predetermined size. The selection frame FW is composed of double black line frames, and a white image is formed between the two black line frames. The selection frame WF configured in this way has a relatively good visibility of the frame with respect to an arbitrary image. Therefore, the extraction area can be easily determined, and the extraction area can be easily set. It is also possible to use a frame in which the user can arbitrarily set the size. The selection frame FW is moved using a pointing device (for example, up / down / left / right keys) mounted on the remote controller 29 to select and determine an image to be extracted from the extraction target images.
[0138]
When an image to be extracted from the extraction target images is selected by the selection frame FW, the selected image (hereinafter referred to as “selection extraction image”) SCPD is displayed at the center of the screen as shown in FIG. Moved and displayed. The portion excluding the selectively extracted image SCPD is masked with a black image. The OSD controller 212 displays “Do you want to use this image?” On the image extraction setting screen, and determines whether or not to use the currently extracted image. If “No” is selected and determined, the extracted image setting mode is terminated and the menu screen is displayed. When “Yes” is selected and decided, “Set display magnification” is displayed on the image extraction setting screen by the OSD controller 212 as shown in FIG.
[0139]
At this time, if one of the display magnifications displayed on the image extraction setting screen is selected, the selected extracted image SCPD is displayed at the display magnification. If a different display magnification is selected, the image is redisplayed at that display magnification. Thereby, it is possible to select a desired display magnification while selecting and displaying different display magnifications several times. Then, a desired display magnification is determined by pressing an execution key (decision key). Note that an arbitrary magnification may be selected as the display magnification.
[0140]
When the image to be extracted and the display magnification are determined, the OSD controller 212 displays “Do you want to save this image?” On the image extraction setting screen as shown in FIG. 26, and the image data representing this image is displayed. It is determined whether or not to save the extracted image data CPD1 in the extracted image memory 224 (FIG. 15). If “No” is selected and determined, the extracted image setting mode is terminated and the menu screen is displayed. If “Yes” is selected and determined, the extracted image data CPD1 is stored in the extracted image memory 224 (FIG. 15). When the storage is completed, the image extraction screen displays “Storage of extracted image is completed”, and extraction of the extracted image is completed (FIG. 27). During the above setting, the menu screen can be restored at any time by pressing the “menu key”.
[0141]
In this projection display apparatus, the user can easily extract an image by selecting an arbitrary extraction target image according to the image extraction setting screen according to the above procedure. In addition, the processing conditions (display magnification) of the extracted image data stored in the extracted image memory 224 can be determined while checking the extracted image.
[0142]
As can be seen from the above description, the video processor 234, the OSD controller 212, the remote control unit 28, and the CPU 20 in this embodiment are included in the image extraction unit and the specific image display control unit in the second aspect of the present invention. Equivalent to.
[0143]
D. Fourth embodiment
FIG. 28 is a block diagram showing the overall configuration of a projection display apparatus as an embodiment according to the second and third aspects of the present invention. The projection display device has the same configuration as that of the projection display device of the third embodiment except that the operation condition determination unit 226 is provided. Therefore, the description thereof is omitted.
[0144]
FIG. 29 is a schematic block diagram showing the configuration of the operating condition determination unit 226. The operating condition determination unit 226 includes an image signal detection unit 242, an apparatus activation detection unit 244, and a determination unit 246. The image signal detection unit 242 receives the synchronization signal WSYNC included in the image signal, and has a function of detecting whether the image signal is input to the projection display device. The apparatus activation detection unit 244 receives the power supply voltage Vcc and has a function of detecting whether the projection display apparatus is activated and can perform projection display. The determination unit 246 has a function of determining whether an image input from the outside can be projected and displayed based on the detection signals D1 and D2 detected by the image signal detection unit 242 or the apparatus activation detection unit 244.
[0145]
FIG. 30 is a time chart showing the operation of the operation condition determination unit 226. FIG. 30A shows the power supply voltage Vcc of the apparatus. FIG. 30B shows an activation detection signal D2 output from the apparatus activation detection unit 244. 30C shows the synchronization signal WSYNC included in the image signal input to the projection display device, and FIG. 30D shows the detection signal D1 output from the image signal detection unit 242. FIG. 30 (e) shows the operation condition determination signal SPDMODE.
[0146]
As shown in FIG. 30 (a), when the power supply voltage Vcc becomes a voltage sufficient to start the operation of the projection display device, the activation detection signal D2 is set to a predetermined value as shown in FIG. 30 (b). It changes from L (low) level to H (high) level after period T2. If a power supply voltage is applied to the projection display device, a specific image can be displayed in a relatively short period. However, in order to be able to display an image input from the outside, it takes time to generate a synchronous clock that is a reference for internal circuit operation. The predetermined period T2 indicates an unstable period in which a power supply voltage is applied to such a projection display device and a specific image can be displayed, but an externally input image is displayed. . When the activation detection signal D2 is at the L level, it indicates that preparation for display is not yet completed, and the operation condition determination signal SPDMODE is at the L level as shown in FIG. 30 (e). . That the operating condition determination signal SPDMODE is at the L level indicates that the projection display device is in the specific image display mode, and display of the specific image is executed. When activation detection signal D2 changes to H level, operation condition determination signal SPDMODE becomes H level. That the operating condition determination signal SPDMODE is at H level indicates that the projection display device is in the normal image display mode, and an image represented by the input image signal is displayed.
[0147]
As shown in FIG. 30C, the image signal detection unit 242 detects whether or not the synchronization signal WSYNC is input at a predetermined cycle interval Tc. When a pulse signal is input at an interval of the synchronization signal period Tc, the synchronization detection signal D1 is at the H level as shown in FIG. When the pulse signal is not detected at the synchronization signal cycle Tc interval, the synchronization detection signal D1 changes to the L level after a predetermined period T1. The predetermined period T1 indicates a detection margin. When the synchronization detection signal D1 is at the L level, the operating condition determination signal SPDMODE is changed to the L level as shown in FIG. 30E, and the display of the specific image is executed.
[0148]
As described above, in the present embodiment, whether or not the operating condition determination unit 226 is in a projection display enabled state after the projection display device is activated and whether an image signal is input to the projection display device. Whether the image input as the normal image display mode is projected and displayed or the specific image described in the third embodiment is projected and displayed as the specific image display mode. be able to.
[0149]
As can be seen from the above description, the operating condition determining unit 226 in the present embodiment corresponds to the operating condition determining unit in the second and third aspects of the present invention. The video processor 234, the OSD controller 212, and the CPU 20 correspond to the image extraction unit and the specific image display control unit in the second and third aspects of the present invention.
Note that the image signal detection unit 242 detects whether or not an image signal is input by the synchronization signal WSYNC, but the detection is not limited to this, and various detection methods are conceivable. For example, when an image signal such as a color signal or a luminance signal is input and the image signal remains a black level signal for a certain period, it may be detected that no image signal is input.
[0150]
The present invention is not limited to the above-described examples and embodiments, and can be implemented in various modes without departing from the gist thereof. For example, the following modifications are possible.
[0151]
In the first to fourth embodiments, the projection display device has been described as an example. However, the present invention is not limited to this and can be applied to various image display devices.
[0152]
In the first embodiment, the superimposition of the extracted image is performed by the two multiplying units 40 and 42 and the one adding unit 44 inside the extracted image superimposing circuit 12 (FIG. 5). 14 may be used. Also in this way, it is possible to obtain a paint overlay effect in which the coefficients (k1, k2) of the multipliers 40, 42 correspond to (1, 0) or (0, 1).
[0153]
In the first embodiment, the superimposition of the extracted image is performed by the two multiplying units 40 and 42 and the one adding unit 44 inside the extracted image superimposing circuit 12 (FIG. 5), but both the coefficients k1 and k2 are used. If the transparent superimposing effect is “1/2”, the multipliers 40 and 42 may not be used. That is, the same transparent superposition effect can be obtained also by performing bit shift in the adding unit 44 so as to erase the lower 1 bit of the added data.
[0154]
In the second embodiment, the superimposition of the extracted image is performed by the data selector 76 (FIG. 14), but a multiplier and an adder shown in FIG. 5 may be used instead. In this way, not only the superimposing effect of the fill but also the transparent superimposing effect can be obtained.
[0155]
In the first and second embodiments, when the extracted image bitmap data is expanded with the memory capacity corresponding to one frame of the image data allocated to the extracted image as shown in FIG. Even if the flag is used instead, the same effect can be obtained. That is, for example, a 1-bit flag is provided in the pixel data of the extracted image bitmap data where the extracted image exists, and the presence or absence of the extracted image can be determined based on the presence or absence of the flag. In this case, the coefficients k1 and k2 of the multipliers 40 and 42 (FIG. 5) in the first embodiment can be changed depending on the presence or absence of the flag, and the selection of the data selector 76 (FIG. 14) in the second embodiment is selected. Can be changed. This makes it possible to obtain the same effect as when using coordinate data.
[0156]
In the first and second embodiments, the extracted image bitmap data BMD1 is expanded and stored in the extracted image bitmap memory 26 or the extracted image memory 24. The extracted image bitmap memory 26 is expanded. The extracted image memory 24 is not limited. That is, other storage areas may be prepared and stored.
[0157]
In the first and second embodiments, only the extracted image extracted by the image extracting unit 74 is stored as the extracted image stored in the extracted image memory 24, but the image stored in the extracted image memory 24 is stored in the extracted image memory 24. Is not limited to this. That is, an image created by another device, for example, an image read by a scanner or an image created by a personal computer may be stored in the extracted image memory 24 in advance. In this way, not only the extracted image cut out in the projection display apparatus but also other images can be superimposed on the original image.
[0158]
In the first and second embodiments, the image to be superimposed on the input image is always stored in the extracted image memory 24. However, the image to be superimposed on the input image is limited to the image previously stored in the extracted image memory 24. Absent. That is, by directly writing the bitmap data of the graphic drawn by the remote controller 29 into the extracted image bitmap memory 26, the drawn image can be superimposed. In this way, it becomes possible to superimpose a drawing image of an arbitrary shape designated by the user with the remote control 29 using a drawing program, for example, a free curve.
[0159]
In the third and fourth embodiments, the case where the specific image is displayed by writing the specific image data SPD1 in the frame memory 222 is described as an example. However, the present invention is not limited to this. For example, the specific image data SPD1 can be written in the OSD memory 213 and displayed by the OSD controller 212 as an OSD image represented by the OSD image data.
[0160]
In the third embodiment, the case where a specific image including an arbitrarily extracted image is displayed using the image extraction unit according to the second aspect of the present invention is described as an example. However, the present invention is not limited to this. is not. In a projection display device that does not include an image extraction unit, a specific image supplied in advance via a computer or a specific image stored in a storage medium and supplied via a data reading device may be displayed.
[0161]
The operating conditions described in the fourth embodiment are limited only to whether or not the projection display apparatus is activated and can perform projection display, and whether or not an image signal is input to the projection display apparatus. Instead, various operating conditions may be set, and a determination circuit corresponding to this may be provided in the operating condition determination unit.
[0162]
In the first and second embodiments, the liquid crystal display panel 16 is used as the light modulation means of the projection display device, but is not limited thereto. In other words, the light modulation means may be any means that can change the luminance in accordance with the image data. For example, a light modulation means using reflection in a specular element arranged according to the pixel may be used, or a CRT or plasma display panel that is not usually called a light modulation means may be used.
[0163]
In the third and fourth embodiments, the liquid crystal light valve 216 is used as the electro-optical device of the projection display device, but the present invention is not limited to this. That is, as the electro-optical device, various devices that emit light that forms an image in accordance with an image signal can be used. For example, a DMD (digital micromirror device) (trademark of TI) may be used, or a CRT or a plasma display panel may be used.
[0164]
In the above embodiment, a part of the configuration realized by hardware may be replaced with software, and conversely, a part of the configuration realized by software may be replaced by hardware.
[0165]
Industrial applicability:
The present invention is applicable to various image display devices such as a projection display device. The projection display device using the present invention can be applied to project an image supplied from, for example, a computer or a video recorder on a screen.
[Brief description of the drawings]
FIG. 1 is a block diagram showing an overall configuration of a projection display apparatus as a first embodiment according to the first aspect of the present invention;
FIG. 2 is a block diagram showing an internal configuration of a video signal conversion circuit 10;
3 is a block diagram showing an example of an internal configuration of a video processor 34. FIG.
FIG. 4 is an explanatory diagram showing a frame memory 22, an extracted image memory 24, and an extracted image bitmap memory 26 in the present embodiment.
FIG. 5 is a block diagram showing an internal configuration of an extracted image superimposing circuit 12;
6 is an explanatory diagram showing a superimposition process between image data stored in the frame memory 22 and extracted image bitmap data BMD1 stored in the extracted image bitmap memory 26. FIG.
7 is an explanatory view showing extracted image bitmap data BMD1 developed in an extracted image bitmap memory 26. FIG.
FIG. 8 is an explanatory diagram illustrating an example of an image projected on the projection screen 104 when an extracted image is superimposed on an image input from a personal computer.
FIG. 9 is an explanatory diagram illustrating an example of an image projected on the projection screen 104 when an extracted image is superimposed on an image input from a personal computer.
10 is an explanatory diagram showing an extracted image bitmap memory 26 when the extracted image shown in FIG. 9 is expanded. FIG.
FIG. 11 is an explanatory diagram showing an example of a projected image when a transparent extracted image is superimposed.
FIG. 12 is a block diagram showing an overall configuration of a projection display apparatus as a second embodiment according to the first aspect of the present invention.
13 is a block diagram showing an internal configuration of a video signal conversion circuit 60. FIG.
14 is a block diagram illustrating an example of an internal configuration of a video processor 62. FIG.
FIG. 15 is a block diagram showing an overall configuration of a projection display apparatus as an embodiment according to the second aspect of the present invention.
16 is a block diagram showing an internal configuration of a video signal processing circuit 210. FIG.
17 is a block diagram illustrating an example of an internal configuration of a video processor 234. FIG.
18 is an explanatory diagram showing an extracted image memory 224. FIG.
FIG. 19 is an explanatory diagram showing an example in which an image input from the outside is displayed on the projection screen 104. FIG.
20 is an explanatory diagram showing an example in which a specific image represented by specific image data SPD1 including extracted image data CPD1 and background image data BGD1 stored in the extracted image memory 224 is displayed on the projection screen 104. FIG.
FIG. 21 is an explanatory diagram showing an example in which extracted images represented by three types of extracted image data CPD1 (A), CPD1 (B), and CPD1 (C) are sequentially selected and displayed on the projection screen 104;
FIG. 22 is an explanatory diagram showing a procedure for cutting out a user logo image from an image input to the projection display apparatus.
FIG. 23 is an explanatory diagram showing a procedure for cutting out a user logo image from an image input to the projection display apparatus.
FIG. 24 is an explanatory diagram showing a procedure for cutting out a user logo image from an image input to the projection display apparatus.
FIG. 25 is an explanatory diagram showing a procedure for cutting a user logo image from an image input to the projection display device.
FIG. 26 is an explanatory diagram showing a procedure for cutting out a user logo image from an image input to the projection display apparatus.
FIG. 27 is an explanatory diagram showing a procedure for cutting out a user logo image from an image input to the projection display apparatus.
FIG. 28 is a block diagram showing an overall configuration of a projection display apparatus as an embodiment according to the second and third aspects of the present invention.
29 is a schematic block diagram illustrating a configuration of an operation condition determination unit 226. FIG.
30 is a time chart showing the operation of the operation condition determining unit 226. FIG.

Claims (7)

A projection display device that projects and displays an image,
A frame memory for storing an image to be displayed as image data;
An image display signal generator for generating an image display signal based on the image data stored in the frame memory;
An electro-optical device that emits light for forming an image in response to the image display signal;
A projection optical system that projects the light emitted by the electro-optical device, and
The projection display device further includes:
An image extraction unit that extracts at least a part of an extraction target image arbitrarily selected from images input from the outside as an extraction image;
An extracted image memory for storing extracted image data representing the extracted image;
An operation condition determination unit for determining a specific operation condition in the projection display device;
A specific image display for displaying a specific image represented by specific image data including the extracted image data stored in the extracted image memory on a display screen when the specific condition is detected by the operating condition determination unit A control unit;
With
The image extraction unit
Display an extraction image setting screen for setting at least the extraction region and the display magnification as an extraction condition for extracting the extraction image,
An extraction area designating image for setting the extraction area is displayed superimposed on the extraction target image,
When a portion to be extracted using the extraction region designation image is set as the extraction region, the selection extraction image data representing the selection extraction image corresponding to the set extraction region is written to the frame memory,
When the display magnification is set, the selected extracted image data is enlarged or reduced at the set display magnification, and the enlarged or reduced selected extracted image data is written to the frame memory.
When the desired display magnification is determined, the selected extracted image data enlarged or reduced at the desired display magnification is stored in the extracted image memory. The projection display device according to claim 1,
The image extraction unit displays a predetermined extraction frame for extracting the extracted image,
The predetermined extraction frame includes a first black line frame and a second black line frame provided inside the first black line frame, and the first black line frame and the second black line frame are included. A projection display device in which a region between the line frames is a white image. The projection display device according to claim 1 or 2,
The extracted image memory stores a plurality of types of extracted image data representing a plurality of types of extracted images,
The specific image display control unit displays a specific image including at least one extracted image selected from the plurality of extracted images on the display screen when the specific operation condition is detected. Projection type display device. The projection display device according to claim 3,
The specific image display control unit is a projection display device that selects and sequentially displays at least two extracted images of the plurality of extracted images. A projection display device according to any one of claims 1 to 4,
The operating condition determination unit determines whether at least one of an image signal input to the projection display device is in a no-input state and a state within a predetermined period after the projection display device is activated. A projection display device that detects the specific operating condition. An image display device for displaying an image,
A frame memory for storing an image to be displayed as image data;
An image display signal generation unit that generates an image display signal based on the image data stored in the frame memory;
An electro-optical device that emits light for forming an image in response to the image display signal;
With
The image display device further includes:
An image extraction unit that extracts at least a part of an extraction target image arbitrarily selected from images input from the outside as an extraction image;
An extracted image memory for storing extracted image data representing the extracted image;
An operation condition determination unit for determining a specific operation condition in the image display device;
A specific image display for displaying a specific image represented by specific image data including the extracted image data stored in the extracted image memory on a display screen when the specific condition is detected by the operating condition determination unit A control unit;
With
The image extraction unit
Display an extraction image setting screen for setting at least the extraction region and the display magnification as an extraction condition for extracting the extraction image,
An extraction area designating image for setting the extraction area is displayed superimposed on the extraction target image,
When a portion to be extracted using the extraction region designation image is set as the extraction region, the selection extraction image data representing the selection extraction image corresponding to the set extraction region is written to the frame memory,
When the display magnification is set, the selected extracted image data is enlarged or reduced at the set display magnification, and the enlarged or reduced selected extracted image data is written to the frame memory.
When the desired display magnification is determined, the selected extracted image data enlarged or reduced at the desired display magnification is stored in the extracted image memory. A method of displaying an image using a projection display device,
Extracting at least a part of an input extraction target image as an extraction image;
Preparing extracted image data representing the extracted image;
Determining a specific operating condition in the projection display device;
A step of displaying a specific image represented by the specific image data including the extracted image data on a display screen when the specific operation condition is detected in the determination step;
With
The extraction step includes
Display an extraction image setting screen for setting at least the extraction region and the display magnification as an extraction condition for extracting the extraction image,
An extraction area designating image for setting the extraction area is displayed superimposed on the extraction target image,
When a portion to be extracted using the extraction region designation image is set as the extraction region, selection extraction image data representing a selection extraction image corresponding to the set extraction region is displayed,
When the display magnification is set, the selected extracted image data is enlarged or reduced at the set display magnification, and the selected extracted image data enlarged or reduced is displayed.
A display method comprising a step of storing, when the desired display magnification is determined, the selected extracted image data enlarged or reduced at the desired display magnification.

Images